Note: You don't have to understand Approximation Algorithms to answer this

Hello.

I need to prove an algorithm approximation by using expectation.

The algorithm takes `x_i \in {0,1,2}`

such that `i\in 1,...n+2`

and there are constants `c_i \in 0,1,2`

such that `i\in 1,...,n`

and would like to find an assignment to the variables such that `x_i +x_(i+1)+x_(i+2) != 0 \mod(3)`

for all `i`

such that the number of indexes such that `x_i +x_(i+2) = c_i \mod(3)`

is maximized.

it does the following:

choose `x_1 , x_2 \in 0,1,2`

independently and uniformly at random and then

for each `i\in 3,...,n+2`

given the values of `x_(i-2),x_(i-1)`

assign to `x_i`

one of two values in `{b\in 0,1,2 | x_(i-1)+x_(i-2)+b != 0 \mod(3)}`

uniformly at random.

the assignment to each `x_i`

is independent for all `x_j`

such the `j<i-2`

.

I need to prove this algorithm gives a `1/3`

approximation to the problem described, using expectation(meaning proving that for some X random variable that we assign to this question, `E[X]=1/3`

)

I am struggling with defining such X and calculating this, I keep getting 2\3 instead of 1\3.

can anyone help with the calculation?